Ubiquitination-mediated regulation of RIP2 in NOD2 signaling and MDP tolerance induction (INM2P.354)

Abstract The cytoplasmic innate immune receptor NOD2 is required for antibacterial immune response. Optimal regulation of NOD2 is essential for controlling bacterial infections and inflammatory disorders. Recently, ubiquitination has emerged as an important posttranslational modification required to control NOD2-signaling. Yet, the specific ubiquitination mechanisms that negatively regulate NOD2-signalling during both acute and chronic (e.g., MDP-tolerance) stimulations are incompletely understood. Through a human genome-wide-RNA-interference screen, we identified an E3-ubiquitin ligase {termed as NOD2 Signaling Regulator (NSR)} as a novel negative-regulator of NOD2-mediated NF-KB, cytokine, and antibacterial responses. Mechanistically, NSR induced K48-linked ubiquitination of RIP2 (NOD2-adaptor), and promoted RIP2 degradation through the endoplasmic-reticulum-associated-degradation (ERAD) pathway. We identified the endoplasmic reticulum as a new regulatory site for NOD2-signaling, where RIP2 was localized and interacted with NSR and ERAD. In vivo NSR knock-down in mice resulted in increased NOD2-mediated NF-KB activation. NSR-mediated RIP2 degradation was critically required for MDP-tolerance induction both in vivo and in vitro. Thus, this study unravels a key molecular mechanism by which NOD2 pathway is attenuated, and provide new directions to understand the role of NOD2 pathway in both infectious and inflammatory diseases.